Installation Instructions

INSTALLING THE COOKTOP

1 INSTALLING THE JUNCTION BOX

Install an approved junction box where it will be easily reached through the front of the cabinet where the cooktop will be located. The cooktop

conduit is 58long.

Install junction box so

 

that it can be reached

*5

through the front of the

Min.

cabinet.

 

 

*7Max. when

 

installing over

 

GSM2100

 

Dishwasher

IMPORTANT: The junction box must be located where it will allow considerable slack in the conduit for serviceability.

INSTALLATION OVER GSM2100 DISHWASHER

The center of the junction box should be 5to 7below the cooktop lip, so it does not interfere with the dishwasher, installation or operation.

Electrical connections must be made before placing the cooktop into the cutout.

3 ATTACH FOAM TAPE

Apply the foam tape around the outer edge of the glass. Do not overlap the foam tape.

Bottom of Cooktop

Foam Tape

Cooktop

Glass

4 LOCATE MOUNTING PARTS

Start one screw through the bracket and into the cooktop (both sides). Do not tighten. Turn the bracket inward to avoid interference when dropping the cooktop into the countertop.

2PROTECT SURFACE OF COOKTOP

Place a towel or tablecloth onto the countertop. Lay the cooktop upside down onto the protected surface.

Bottom of Cooktop

Cloth under Cooktop

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GE JP256 Installing the Cooktop, Installing the Junction BOX, Attach Foam Tape, Locate Mounting Parts

JP256 specifications

The GE JP256 is an advanced gas turbine designed for high-efficiency power generation, catering to the growing energy demands of both industrial and municipal applications. As part of General Electric's renowned fleet of gas turbines, the JP256 boasts impressive performance metrics that set it apart in the competitive energy landscape.

One of the standout features of the GE JP256 is its combined cycle capability. This technology allows the turbine to work alongside steam turbines, enabling a more efficient use of fuel and improving overall thermal efficiency. This combined cycle setup can achieve efficiencies exceeding 60%, which helps operators reduce fuel costs and minimize greenhouse gas emissions. This is particularly crucial in today's energy market, where there is a strong push toward sustainable practices.

The JP256 is designed with a simple cycle rating, delivering up to 256 MW of power at ISO conditions. This makes it suitable for both peaking and base-load generation, providing flexibility in meeting fluctuating energy demands. Additionally, its low operational and maintenance costs make it an attractive option for utility companies looking to optimize their energy generation portfolio.

In terms of technology, the GE JP256 employs advanced materials and manufacturing techniques, enhancing its durability and performance. The turbine features a high-efficiency airfoil design, which improves aerodynamics and contributes to overall efficiency gains. Its advanced control systems utilize real-time data analytics to optimize performance, ensuring that the turbine operates at maximum efficiency under varying load conditions.

The characteristics of the JP256 also include a modular design that simplifies maintenance and reduces downtime. This design not only eases the replacement of components but also shortens the time required for routine maintenance activities. Moreover, GE’s commitment to innovation is reflected in the turbine's compatibility with various fuels, including natural gas and biogas, allowing for greater operational flexibility.

Noise reduction technologies are also integral to the JP256, making it an optimal choice for installations in urban areas where emissions and noise control are critical. Its compact footprint allows for easier integration into existing plants without requiring significant alterations to infrastructure.

In summary, the GE JP256 gas turbine stands out for its combined cycle capabilities, high efficiency, low operational costs, and advanced technologies. Designed for versatility and sustainability, it is a comprehensive solution for meeting the modern demands of power generation.